Heat storage control system



C- 12, 1948 c. M. osTr-:RHELD i 2,450,983

HEAT STORAGE CONTROL SYSTEM Filed April 27, 1945 2 Sheets-Sheet l /af Y "y 35' j '75 \7/ I 6.9 /07 7 IN VEN TOR.

MX x @b CLARA/ .05m/wap Oct. l2, 1948. c. M. OSTERHELD 2,450,983

HEAT sToEAEE- coETEoL SYSTEM Filed April 27, 1945 2 Sheets-Sheet 2 F67- ff INI/EN TOR.v CLA/Ek .USER/faz? Patented Oct. 12, 1948 HEAT STORAGE CONTROL SYSTEM Clark M. Osterheld, Stoughton, Wis., assignor to McGraw Electric Company, Elgin, Ill., a corporation of Delaware Application April 27, 1945, Serial No. 590,655

9 Claims.

My invention relates to house heating systems' and particularly to systems for controlling the storage of electrically generated heat in heat storage masses.

An object of my invention is to provide a controlv system for controlling the energization of an electric heater associated with a heat storage mass for generating and storing heat mainly during the night.

Another object of my invention is to provide a control system for generating and storing heat in heat storage masses, which system is operative to cause a fixed delay period after either the start of darkness or of an oli-peak period, the length of such delay period being different in accordance with the temperature of the heat storage mass and being shorter the lower the temperature of the heatstorage mass.

Another object of my invention is to provide a control system f or storing heat in heat storage masses operative to cause a continuation of the energization of an electric heater and to have a continuation of the storage of heat after the start of daylight or the start of an onpeak period in case the temperature of the heat storage mass is kstill below a predetermined maximum Value at the start of daylight or the start of an on-peak period, such energization continuing until the temperature of the heat storage mass reaches a predetermined desired maximum value.

Other objects of my invention will either be apparent from a description of several forms of systems embodying my invention or will be pointed out in the course of such description and set forth in the appended claims.

In the drawings, Figure 1 is a diagram of connections for the controlof the heating current traversing an electric heater over the contacts of thermal switches and an ofi-peak time controlled switch,

f Fig, 2 is a similar diagram of connections showing the use of an electro-magnetic control switch, the energization of which is controlled by a plurality of thermal switches,

Fig. 3 is a diagram of connections showing the use of a light-sensitive cell for controlling the energization of the electric heater, and,

Fig. 4 is a somewhat similar diagram of connections embodying a second electro-magnetic heater control switch, controlled by a plurality of thermal switches.

Referring'rst of all to Fig 1 of the drawings, I have there shown generally only a room II having a hot 4air inlet conduit I3, which conduit is connected with a closed chamber I5 in which the heat storage mass and certain control devices to be hereinafter described may be located. It is to be understood that the representation of a room II is to be taken as representation of any number oi rooms, the temperature of which is to be maintained at predetermined points during a twenty-four-hour day by a thermostat I1, the use and connections o-f which will be hereinafter set forth in detail.

The storage chamber I5 may be lled with a mass I9 of a suitable heat storage material which is adapted to be heated by one or more electric heaters 2|. Whilevl have illustrated the heat storage mass I9 as well as the electric heater 2I schematically only, I desire it to be understood that the design and construction of either the heat storage mass or of the electric heater constitutes no part of my present invention.

I provide a pair of supply circuit conductors 23 and 25,' conductor 23 being connected to one terminal of the thermostat I1 by a conductor 21 while the other terminal of thermostat I1 is connected by a conductor 29 to one terminal of a motor 3| having a fan 33 mounted on its shaft.

The other terminal of motor 3l may be connected by a conductor 35 to the second supply circuit conductor 25 either Idirectly or indirectly. The an 33 is adapted to be positioned in a blower opening 31 in a part of the outer wall of the chamber I5 so that upon rotation of the fan a flow of air will be established starting with the room II and then through a cold air conduit 39 into the chamber I5, past the heated masses I9 of heat storage material and then upwardly through the hot air inlet conduit I3 into the room II. y It is obvious that when the temperature of the room Il has reached a predetermined or desired maximum that the thermostat I1 will move to the o-pen position as shown for instance in Fig. l to thereby cause deenergization of the fan motor 3I.

Since it is desirable and possible to energize the heater 2I with current during off-peak periods on the supply system, I Iprovide a time controlled switch 4I comprising a pair of contact arms 43 and 45. These contact arms are adapted to be in open position during on-peak periods of a twenty-four-hour day and are adapted to be in engaged or closed position during off-peak periods, they being actuated or moved into the desired positions by a continuously operative timing means such as is now commonly used for such purposes.

I Iprovide further a plurality of thermostats or thermal switches 41, l'I9 and `5I which are to be understood as being in good heat receiving relation relative to the heat storage mass I9 although not so shown. For illustrative purposes, I may point out that the thermal switch 41 is adapted to be in closed position when it is subject to temperature below a lvalue on the order of 800 F. while it is in open position when subject to a temperature above, say 800 F. The thermal switch 49 is adapted to be in closed position when sub- .ject to temperature below 500 F. while switch 5I is adapted to be in closed position when subject to temperature below, say 200 F.- while both switches are adapted to be in open position when subject to temperature of 500 F. and 200 F. respectively or over. I do not desire to be limited to the values of 800 F., 500 F. and 200 F., but merely mention them for illustrative purposes.

I provide further a thermally-actuable time delay switch comprising a bimetal bar 53 having one end thereof mounted on a fixed contact member which contact member is adapted to be connectedby a conductor 55 to one terminal-of switch 41 aswell as to one terminal of switch 49. I provide further a second'thermally actuable time delay switch comprising a bimetal bar 51 having one end thereof xedly secured to a fixed contact member which is adapted to be connected to certain terminals of switches 49 and 5I by a conductor 59'; Bimetal bar 53`has operatively assoelated therewith a relatively small heating coil 6I while bimetal bar 51 has operatively associated therewith a relatively small heating coil 63.

The first supply circuit conductor 23 is connected with contact arm 43 while the second contact arm 45 is connected by a conductor 65 with one terminal of heating coil 63, with oneterminal of the second thermal time delay switch, with one terminal of heating coil 6|-, with oneterminal of the-first thermal time delay switch and finally with that terminal of switch which is adapted to be engaged with and disengaged from the bimetal bar. The Vfirst contact of switch 41 is connected by a conductor 61 toene-terminal of heater 2| while the'other terminal of heater'2I isconnected by a conductor 69 to one terminal of a -coil 1|, the other terminal of whichis connected to the second supply circuit conductor 25. The coil 1| is part of; an electro-magnetic switch comprising in addition an armature core 13 having connected therewith a contact bridging member which isv adapted to be engaged` with and disengaged from two xed contacts 11- and 19, which are respectively connected with the. contact arms 45sand 43.

Let it now be assumed that contact arms 43` and 45Yhave been moved into engagement with each other at the start of an oli-peak period which, for illustrative purposes, may be assumed to be l2 midnight. The two heating coils 6| and 63 will immeditealy be energized and it is to be understood that the wattage transformed intoheat in coil 6I is such that it will cause increase of temperature of the bimetal bar 53 so that it will move into engagement with its cooperating contact member in` about four hours while the Wattage transformedl into heat in heatingV coil 63will require only two hours to cause closure of the bimetal bar 5.1 and engagement with the ilxed contact member.

Let it be further assumedthat thetemperature of the heat storage mass is on the order of 600 F. so that switches 49 and 5|' will be in the open position while switch 41 will be in the closedposition.. In aboutfour hours after start. of an. oi-

peak period and closure of the time controlled switch 4| an energizing circuit through 'seater 2| will be closed traceable as follows: from supply circuit conductor 23, through the closed switch 4|, conductor 65, bimetal bar 53, conductor 55, through closed switch 41, conductor 61, heater 2| and then through conductor 69 and coil 1I to the second supply circuit conductor 251 This energization of heater 2| will be effectivel to store additional heat in the heat storage mass |9, the time delay as well as the temperature at which switch 41 is closed and the time delay of bimetal bar 53 being so selected that in the two hours remaining of an off-peak period, which is assumed to end at 6 a. m., suicient heat will be generated by heater 2| to cause a temperature rise of the heat storage mass to a value on the order of 800 F. If the temperature of the heat storage mass I9 should be just below the point of opening of switch 41 at the time of opening of time controlled switch 4|; then the heater 2| will continue to be energized' by. the control switch 13, while if the temperature of the heat storage mass I9 is slightly above the value at which switch 41 opens before opening of time controlled switch 4|, switch 41 will open before opening of the time controlled switch 4| and deenergize heater 2|.

Let it now be assumed that greater demands were made during the preceding day for heat so that the temperaturel of the heat storage mass has dropped to below 500 F. at the start of an off-peak period. Thenswitch 41 as well as switch 49 will be in closed position, While switch 5| is stillV in open position. Hence the energized heating coil 63 of the bimetal bar 51 willoperate within two hours to cause movement of bimetal bar 51 into closed position with the result that an ener-- gizing circuit is closed-through heater 2| traceable as follows: from supply circuit conductor 23 through the closed switch 4|', conductor 15, closedv bimetal bar 51, conductor 59, through the two switches 49and 4'1, through conductorl, heater 2|, conductor 69 through coil 1 I, and from there to the second supply circuit conductor 25. It is immaterial whether the temperature of the heatI storage mass is 400 F., or 300 F., or any value below that at which closure of switch 49 is effected and above 200 F., closing of switch 49 and energzation of the heater 2| will take place, after closure of the timecontrol'switch 4|, with aV time delay on the order of two hours, thereby providing plenty of time for increasing the temperature of the heat storage material to a value ilrst over 500 F. and then over 800 F.

Now let it be assumed that the demand for heat was exhaustive as may happenY on a. very cold winterday, so thatthe temperature of the heat storage mass has been reduced at the start of an off-peak period to a value'below 200 F; In this case energization of heater 2| will be effected immediately upon closure of the time control switch 4| through a circuit traceable as follows: from supply circuit conductor 23, through closed switch 4|, conductor 65, then through the closed switches 5I, 49, 41, through conductor 61', and heater 2|, then through conductor 69. and coil1f| to the second supply` circuit conductor 25. This will therefore give substantially six hours to bring up theY temperatureof the heat storage mass I9 to a value about 800 F., it being. understood that thevselection of thetime delay, of the amount of energy transmittediinto'heatin heater 2^I as well as-'the'setting of, particularly, switch 41A is such that the desired temperature rise of theheat storage mass will be eiected within an off-peak period. f

vfLet'it be assumed, however, that the call for heat ha-s been continued during the oil-peak period and that the temperature of the heat storage massv I9 was not 800 F. or slightly beyond at the time of the start of an on-peak period at or about 6:00 a. m. in the morning. It is evident thatthe heater current controlled coil 1| of the electro-magnetic switch will cause upward movement of the contact bridging member into engagement with fixed contacts 11 and 19 and that this engagement will' continue for as long as current flow through coil 1| continues. This continued current flow of the heater current through coil 1| will maintain the contact bridging member 15 in .engagement with fixed contacts 11 and 19 shunting the time-controlled switch 4|' and this condition will continue until the circuit through heater 2| is interrupted by switch 41 when the temperature of the heat storage mass I9 has been increased to 800 F. or over irrespective of whether the time controlled switch 4| is opened at the end of the off-peak period.

Referring now to Fig. 2 of the drawings, I have `there'illustrated a modied diagram of connections, in which an electro-magnetic relay 8| is employed because of the fact that the current traversing heater 2| is much greater than can be carried by bimetal bars as in the switches 41, 49, and5|. Electro-magnetic switch 8| comprises a coil 83, an armature core 85 having secured there- `to a contact bridging member 81 which is adapted tobe engaged with and disengaged from a pair of xed contacts 89 and 9|. Contact 9| is connected by a conductor 93 to contact arm 45, while fixed contact 89 is connected by a conductor -95 to one terminal of heater 2|,the other terminal of which may be connected to coil 1| of an electro-magnetic switch by a conductor 69. I provide three thermally actuable switches comprising bimetal bars 91, 99 and |0|, which are connected in series circuit relatively to each other. A conductor |03 connects the upper terminal of coil 83 to one terminal of switch 91 while the ytwo yadjacent contacts of switches 91 and 99 are connected by a conductor |05 to the xed contact of a first thermal time delay switch comprising a bimetal bar I 01. The junction of switches 99 and |0| is connected by a conductor |09 with'the fixed terminal of a second time detially four hours while heating coil I I9 will cause closure of bimetal bar I I I in about two hours.

Substantially the same comments apply to Fig. 2 of the drawings as were hereinbefore made in connection with Fig. 1 of the drawings, it being understood that after closure of the time controlled switch 4| at the start of an off-peak period both heating coils ||1 and I I9 are energized and that they will cause closure of bimetal bars |01 and I II after time delays on the order of fourhours and of two hours respectively so that in case, for instance, the temperature of the heat storage mass I9 is on the order of 600 F., switch 91 will be closed with the result that contact bridging member 81 will be moved into engagement with xed contacts 89 and 9| at the end of about four hours after start of an'offpeak period whereby heater 2| will be energized. The operation of coil 1| 'of the electro-magnetically actuated switch is substantially the same as was hereinbefore set forth in connection with Fig. 1 of the drawings.

Referring now to Fig. 3 of the drawings, I have there shown the use of a light-sensitive cell |2| to nx the time when energization of. the heater 2| is to be prevented, at least during a part of such time. Light-sensitive cell 2| is of the kind which becomes conductive during daylight hours and becomes non-conductive during darkness and it is to be understood that lightsensitive cell |2| is subject to daylight and to darkness. One terminal of light-sensitive cell |2| is connected to the second supply circuit conductor 25 while the other terminal is connected by a conductor |23 to one terminal of a coil |25 of an electro-magnetic relay comprising in addition to coil |25 an armature core |21, a contact bridging member |29 which is adapted to engage with and be disengaged from a pair of xed contacts |3| and |33 of which contact |33 is connected to the rst supply circuit conductor 23.

I provide further two thermally actuable time delay switches, the rst comprising a bimetal bar |35 and the second comprising a bimetal bar |31 together with a small heating coil |39 for bimetal bar |35 and a small heating coil |4| for bimetal bar |31. The wattage generated in heating coil |39 operatively associated with bimetal bar 35 is such that bimetal bar I 35 will be moved into lengagement with its nxed contact member after a time delay on the order of seven hours while the Wattage transformed into heat in heating coil |4| is such as to cause closure of bimetal bar |31 after about three hours. Conductor |43 connects fixed contact |3| with fixed contacts engaged by bimetal bars |35 and |31 as Well as with a conductor |45 which is connected with a iixed contact of a third thermostat or thermal switch |5| which switch is adapted to be in open position at temperatures over 200 F., it being understood that switches |41, |49 and |5| are in close heat-receiving relation Iwith heat storage mass I9. Conductor |53 connects one terminal of switch |49 to the xed terminal of bimetal bar 31 while conductor |55 connects the fixed contact of bimetal bar |41 with xed contact of bimetal bar |35 as well as with one terminal of heating coil |39, the other terminal of which is connected to conductor |43. A con'- ductor |51 connects the contacts on which the bimetal bars .of switches |41, |49 and |5| are mounted to one terminal of heater 2|, the other terminal of which is connected by a conductor 69 to one terminal of coil 1| of an electro-magnetic switch.

Let it now be assumed that the temperature of the heat storage mass |9 is on the order of 600 F. with the result that switch |41 will be closed while switches |49 and |5| Iwill be opened. As soon as .darkness falls the light-sensitive cell |2I becomes non-conducting with the result that contact bridging member |29 drops into engagement with xed contacts |3I and 33. Thiseffects energization of the heating coils |39 and |4| with the result that at the end of seven hours the bimetal bar |35 has been moved into engagement with its fixed contact member wherebyY ari. energizing. circuit. through Aheater 2l is closed; traceable as followsz. from supply circuit. conductor 23, throughk the engaged contacts I3I, |33 and. contact bridging member |29, through conductor |43, through the closed bimetal bar |35, conductor |55, through the bimetal bar of switch I4'I., conductor |51, heater 2|, through conductor 69 and coil 'II to the second supply circuit conductor 25. Since the bimetalbar I49is out of engagement with its cooperating contact, the closure of bimetal bar |31 at the end of three hours'will have noeffect on heater 2|.

The reason that the design, construction and adjustmentV of coil |39 and its eiect upon bimetal bar. |35 is different from those shown in Figs. 1 andV 2 is because of the fact that darkness falls in the. late. afternoon. hours during' mid-winter so that it is desirable to have a longer time delay period` after fall of darkness than after the start of an oi-peak period.

Substantially the same. further comments apply toFig. 3 of the drawings as were made hereinbefore in regard to the diagrams of Figs. 1 and 2' respectively and it is not thought necessary to repeat them.

Referring now to Fig. 4 of the drawings, I have there' shown a modiiiedl diagram of connections embodying an electro-magnetic heater circuit control switch 8| which may be substantially the same as lthat shown in Fig. 2 of the drawings.

Let it now be assumed that the temperature of t-heV heat storage I9 is on the order of 600 at the fall of darkness; As soon as the light-sensitive cell |2I becomes non-conducting contact bridging member |29 will drop into engagement with fixed' contacts |3I and |331thereby closing'a circuit through the heating coils |39-and MI. Heating coil |39 will cause closure of bimetal bar |35 after a time delay on the order of seven hours and since only switch 91 is closed while switches 99 ancl- |0| are open, the quicker closure of bimetal bar |31 which may close after a time delay on the order of three hours, has no effect upon energization of the heater 2 I. When after seven hours delay the bimetal bar |35 closes, it causes energization of the coil 83 with engagement ofr the contact bridging member 81 with xed contacts 89' and 9|, which closes an energizing circuit through heater 2 I, traceable as follows: from supply circuit conductor 23, through fixed' contacts I3'I, |133 and contact bridging member |29, through' conductor |43, through contactbridging member 8l and iixed contacts 89 and 9|, through conductor 93, heater 2|, and through conductor 6'9,.coil 'II to the second supply circuit conductor 25.

Substantially the same comments as made hereinbefore in connection with Fig. 1, and particularly Fig. 2 of the drawings, apply equally well here and it is not thought necessary to repeat them. In case of break of daylight'. before the temperature of the heat storage. mass I9 has reached 899 F. or slightly over, the heater-current controlled coil II of the electromagnetic switch, the contact bridging number of whichis in engagement with the fixed contacts will continue energization of heater 2| until such time when the temperatures of thev heat storage mass i9 has reached a value suilciently high to cause disengagement between the bimetal bar of switch 9'I and its Xed contact member whereby enervgization of coil 83 is interrupted whereby the entire system is deenergized.

Itisltherefore obvious that the various systems shown in the drawings and described in the speci# iication are effective to prevent energization of the electric heater associated with the heat storage mass except during the night andv in the case of certain ofsaid diagrams of connections during a predetermined part of the night, namely the off-peak period.

It is further obvious that the various systems of control shown in Figs. 1 to 4 inclusivel are efective to continue the energization of the heater operatively associated with a heat storage mass, into either the period of daylight or into the onpeak period in case the temperature of the heat storage mass is below a predetermined desired value at daybreak or at the end of an off-peak period.

Further modications may be made in the systems embodying my invention without departing from the spirit and scope thereof and all such modifications clearly coming within the scope of the appended claims shall be considered a part of my invention.

I claim as my invention:

l. An off-peak heat storage system for heating a heat storage mass, comprising an electric heater for said mass, a light-sensitive cell subject to daylight and to'darkness, a plurality of thermostat: in a close heat-receiving relation to said heatstorage mass and adapted to move to closed position at different temperature values of said heat storage mass, a plurality of time delay relays electrically connected in series electric circuit with certain of said thermostats, each relay coinprising a normally open thermally-actuable member and aheating coil therefor, and a switch controlled by said light-sensitive cell for energizing the heating coils of time-delay relays after fall of darkness to cause closure of said thermallyactuable member after a predetermined period of time, and energization of said electric heater;

2; An ofi-peak heat storage system for heating a heat storage mass, comprising an electric heater for said mass, a light-sensitive cell subject to day'- light and to darkness, a plurality of thermostat: in close heat-receiving relation to said' heat.- storage mass and adapted to move to closed position, at' different temperature values of said heat storage mass, a plurality of time delay relays electrically connected in series electric circuit with certain of said thcrmostats, each relay comprising a normally open thermally-actuable member and a heating coil-therefor, and a switch controlled by said light-sensitive cell for energizing the heating coils of time-delay relays after fall of darkness to cause closure ofv said thermallyactuable member after a predetermined period of time and energization of said electric heater, said period of time decreasing with decrease of temperature of the heat storage mass.

3. An off-peak heat storage system for heating a heat storage mass, comprising an electric heater for saidv mass, a light-sensitive cell subject to daylight and to darkness, a plurality of` thermostats in close heat-receiving relationv to said heatstorage mass and adapted4 to move to closed position at different temperature values of said. heat storage mass, a first electromagnetic switch controlled by said' light-sensitive cell. and adapted to be in open` position when said light-sensitive cell is subject to daylight, a second electromagnetic switch. connected in series electric circuit with saidifirst electromagnetic switch, said two electromagnetic switches being adapted to jointly control the energization of said heater, a plurality of time delay relays electrically connected. in

series electric circuit with certain of said thermostats and with the coil of said second electromagnetic switch, each time delay relay comprising a normally open thermally-actuable member and a heating coil adapted to be energized by said first electromagnetic switch after fall of darkness to cause closure of said thermally-actuable members after different predetermined periods of time and energization of said electric heater upon closure of that thermally-actuable member adapted to being closed in the shortest period of time.

4. An o-peak heat storage system for heating a heat storage mass, comprising an electric heater for said mass, a light-sensitive cell subject to daylight and to darkness, an electromagnetic switch controlled by said cell and adapted to be in closed position after fall of darkness and adapted to control the energization of said electric heater, a plurality of thermostats, positioned in close heat-receiving relation to said heat storage mass and adapted to move into closed position at temperatures on the order of 800 F., 500 F. and 200 F. respectively, time delay relays electrically connected in series circuit with said thermostats closing at 800 F. and 500 F. respectively, each time delay relay including a normally open thermally-actuable member and a h'eating coil adapted to be energized upon closure of said rst electromagnetic switch to cause closure of its associated thermally-actuated member after a predetermined period of time and energization of the electric heater, the length of said period of time decreasing with decrease of temperature of the heat storage mass at fall of darkness.

5. A system as set forth in claim 4 in which the thermostat adapted to close at 200 F. is connected directly in series with said electromagnetic switch to cause energization of said electric heater immediately upon closure of said electromagnetic switch at nightfall.

6. A heat storage system for heating a heat storage mass, comprising an electric heater for said mass, an electric circuit for said heater having a switch therein, means for causing said switch to be in open position for part of a twenty four-hour day and in closed position for the rest of said twenty-four-hour day, means controlled jointly by said rst mentioned means and by the temperature of the heat storage mass for selectively causing energization of said heater after different lengths of time after closure of said switch in accordance with the temperature of the heat storage mass, heater-current .controlled switching means connected in shunt with said switch for continuing energization of said heater after opening of said switch in case the temperature of the heat storage mass is below a predetermined value at that time.

'7. A heat storage system for heating a heat storage mass, comprising an electric heater for said mass, an electric circuit for said heater, a switch in said circuit, means for causing said switch to be in open position for part of a twentyfour-hour day and in closed position for the rest of said twenty-four-hour day, means controlled jointly by said first named means and by the temperature of the heat storage mass for selectively causing energization of said heater a rst predetermined length of time after closure of said switch in case the temperature of said heat storage mass is above a predetermined value and a second predetermined length of time after closure of said switch in case the temperature of said heat storage mass is below said predetermined value, heater-current controlled switching means connected in shunt with said switch for continuing energization of said heater after opening of said switch' in case the temperature of the heat storage mass is below a predetermined maximum value at that time, the energization continuing until the temperature of the heat storage mass has reached said predetermined maximum value.

8. A heat storage system for heating a heat storage mass, comprising an electric heater for said mass, and an electric circuit for said heater having a switch therein, means for causing said switch to be in open position for part of a twentyfour-hour day and in closed position for the rest of said day, a plurality of thermostats in close heat-receiving relation to said heat storage mass and adapted to move to closed position at different temperature values thereof, a plurality of time-delay relays connected in series electric circuit with certain of said thermostats, each relay comprising a normally-open thermally-actuable member and a heating coil adapted to be energzed upon closure of said switch to cause closure of said thermally-actuable member after a predetermined period of time, and energization of said electric heater.

9. The combination of the immediately preceding claim wherein said switch is controlled by a clock.

CLARK M. OSTERHELD.

REFERENCES CITED The following references are of record in the file of this patent:

.UNITED STATES PATENTS Number Name Date 2,238,624 Clark Apr. 15, 1941 2,266,146 Biebel Dec. 16, 1941 2,266,147 Biebel Dec. 16, 1941 2,368,774 Osterheld Feb. 19, 1945 2,377,440 Osterheld June 5, 1945. 

